Publication detail
Femtosecond laser ablation elemental mass spectrometry
HERGENRODER, R., SAMEK, O., HOMMES, V.
Original Title
Femtosecond laser ablation elemental mass spectrometry
Type
journal article - other
Language
English
Original Abstract
Laser ablation mass spectrometry (LA-MS) has always been an interesting method for the elemental analysis of solid samples. Chemical analysis with a laser requires small amounts of material. Depending on the analytical detection system, subpicogram quantities may be sufficient. In addition, a focused laser beam permits the spatial characterization of heterogeneity in solid samples typically with micrometer resolution in terms of lateral and depth dimensions. With the advent of high-energy, ultra-short pulse lasers, new possibilities arise. The task of this review is to discuss the principle differences between the ablation process of short (> 1 ps) and ultra-short (< 1 ps) pulses. Based on the timescales and the energy balance of the process that underlies an ablation event, it will be shown that ultra-short pulses are less thermal and cause less collateral damages than longer pulses. The confinement of the pulse energy to the focal region guarantees a better spatial resolution in all dimensions and improves the analytical figures of merit (e.g., fractionation). Applications that demonstrate these features and that will be presented are in-depth profiling of multi-layer samples and the elemental analysis of biological materials.
Keywords
femtosecond laser; laser ablation; time-of-flight; inductively coupled plasma mass spectrometry
Authors
HERGENRODER, R., SAMEK, O., HOMMES, V.
RIV year
2006
Released
1. 6. 2006
ISBN
0277-7037
Periodical
Mass Spectrometry Reviews
Year of study
25
Number
4
State
United States of America
Pages from
21
Pages to
25
Pages count
6
BibTex
@article{BUT43554,
author="Ota {Samek}",
title="Femtosecond laser ablation elemental mass spectrometry",
journal="Mass Spectrometry Reviews",
year="2006",
volume="25",
number="4",
pages="21--25",
issn="0277-7037"
}